Optical interconnects with hybrid construction

ABSTRACT

Disclosed is a hybrid waveguide structure, wherein a core or cladding has a hybrid section or “button” of a different optical property such as refractive index from the major portion of the core or cladding, respectively. The hybrid section can be made of a passive material or an electro-optic material. Methods of making a hybrid waveguide structure are also disclosed. These methods include rib-based methods and trench-based methods, and in either of these methods, a temporary filler is used in many instances to incorporate the hybrid section into the hybrid waveguide structure.

This application is a continuation of Ser. No. 08/814,399 filed Mar. 11,1997 now U.S. Pat. No. 6,144,779.

FIELD OF INVENTION

This invention relates to devices that have optical interconnects, suchas digital electro-optic switches and multiplexers. More particularly,this invention utilizes a hybrid waveguide structure referred to hereinas a “button” in an optical interconnect. New processes are alsopresented for fabricating circuits that incorporate these buttons.

BACKGROUND OF THE INVENTION

Optical devices such as optical waveguides and switches are used incommunications and data transfer equipment to transfer information fromone location to another and to switch the information to a desiredoutput. The information is in the form of a continuous or a pulsingoptical signal.

These optical devices contain a core or cores made of a material thattransmits light of the desired wavelength and cladding that abuts atleast one side of a core. Optical waveguides are used to carry opticalsignals from one location to another. Multiple cores are used to forme.g. switches to switch an optical signal to a desired output core,filters to filter one or more optical signals of a particularwavelength, or multiplexers to combine or separate optical signals ofdifferent wavelengths. Optical cores can be linear, but often opticalcores must curve in order to direct a signal from one location toanother within the confines of a small space.

One major objective of electro-optic device research is to reduce thesize of components. There are two benefits from reducing the size ofcomponents: (1) devices such as waveguides and electro-optic switchesare shorter and/or smaller, allowing more components to be placed withinan integrated device; and (2) signals are transmitted between componentsmore quickly, which increases the speed at which data is transferred.

Currently, if the direction of an optical signal is to be changed 90°,the core must be fabricated to have a radius of approximately 10 mm toavoid losing much of the optical signal to the cladding in the curvedsection. Consequently, every 90° turn that is incorporated along thelength of a device adds at least 10 mm to the length or width of thedevice.

Another objective of electro-optic device research is to providecomponents that can be manufactured such that their switchingcharacteristics are more consistent, so that a switch fabricated todayperforms essentially the same as a switch fabricated a month or yearfrom today. Many switches have switching characteristics that areextremely sensitive to the voltage of the signal used to switch theoptical signal from one output core to another or to distribute theoptical signal among multiple cores. These switches are quite sensitiveto manufacturing variances, and significant variations occur from onebatch to the next of these switches or even within a batch of theseswitches.

An interferometric modulator as illustrated in FIG. 1 is a modulatorwhose performance is extremely sensitive to the voltage used to modulatethe optical signal. This type of switch can be fabricated by diffusing ametal such as titanium into an electro-optic crystal such as LiNbO₃ toform the cores. The titanium-diffused portion of the crystal (which isalso electro-optic) has a higher refractive index than the virginportion of the crystal, and consequently, the titanium-diffused portionacts as cores which carry an optical signal.

The interferometric modulator 100 as illustrated in FIG. 1 uses multiplecores to modify an input optical signal. The input optical signal issplit between two input cores 1 10 and 120, and the two input coresseparate from one another a sufficient distance that the cores do notevanescently couple. The optical signal in core 1 10 travels throughthat core unmodified. The second core 120 has a set of electrodes 130fabricated above it, so that an electric field can be applied to theelectro-optic material in that core. The optical signal in the secondcore can be unmodified as it travels through the core, or the opticalsignal can have its phase shifted in response to the electric fieldcreated by electrodes above and on either side of the core. The twocores subsequently recombine to form one core, where the optical signalsadd to one another. If the optical signals from each core are in phasein the section where the cores recombine to form one core, the signalsadd to form an optical signal having the same wavelength and phase. Ifthe optical signals are out of phase, the optical signal that is outputdepends on how much the phase of the signal was shifted as it traveledthrough core 120.

The interferometric modulator of FIG. 1 can be very difficult tofabricate consistently. The amount of titanium diffused into the crystalis highly dependent on processing conditions, and the minor variationsin processing conditions that occur during normal manufacturingprocesses cause an interferometric modulator produced in one batch tofunction very differently from an interferometric modulator made inanother batch of switches when an identical electric field is applied toboth switches.

It is an object of this invention to provide hybrid waveguide structuressuch as optical waveguides that have improved properties such as greaterisolation, tight turning radii, or different propagationcharacteristics. It is another object of this invention to providehybrid waveguide structures such as electro-optic switches that haveless variance in their intended use because of the switch design and/orbecause of the process by which the switches are manufactured.

SUMMARY OF THE INVENTION

The invention provides a hybrid waveguide structure comprised of atleast one core and cladding. At least a portion of a core and/or asection of its surrounding cladding has optical properties that differfrom the optical properties of a neighboring core or portion of the samecore or cladding area, respectively. Thus, in a hybrid waveguidestructure, a core may have a short section along the length of the corethat has a refractive index which differs from the refractive index ofother sections along the length of the core. Additionally oralternatively, the hybrid waveguide structure has a core in which itsrefractive index differs from the refractive index of anotherevanescently-coupled core, and/or the cladding near a core may have asection that has a refractive index which differs from the remainingcladding around the core. The hybrid portion of the hybrid waveguidestructure is referred to as a “button” herein.

The invention also provides a hybrid electro-optic structure which has aportion of a core or a region of cladding made of an electro-opticmaterial whose refractive index can differ from the refractive index ofa neighboring portion of the same core or region of cladding,respectively. The refractive index of the electro-optic material candiffer from the refractive index of its neighboring material in thepresence of an applied electric field, or the refractive index of theelectro-optic material can differ from the refractive index of itsneighboring material in the absence of an applied electric field.

The invention also provides an integrated device having a hybridwaveguide structure and/or a hybrid electro-optic structure as describedabove.

In one embodiment, the invention provides a hybrid waveguide structurewhich in cross-section (as illustrated in FIG. 2) comprises threesections, a lower section 210, a middle section 220, and an uppersection 230. Each section has a first, second, and third region when thestructure has at least one core, and each section has a fourth and fifthregion when the structure has at least two cores that are evanescentlycoupled. For a single-core structure, the regions are each formed of amaterial having a refractive index such that the second region of themiddle section (222) is a core, and the first and third regions of themiddle section are cladding under light-transmitting conditions. For astructure having two or more evanescently-coupled cores, the regions areeach formed of a material having a refractive index sufficient that thesecond and fourth regions of the middle section (222 and 224,respectively) are cores and the first, third, and fifth regions (221,223, and 225, respectively) are cladding under light transmittingconditions. The second and fourth middle regions are also spacedsufficiently closely that the second and fourth regions evanescentlycouple when light is transmitted into at least one of the second andfourth regions. The second middle region 222 is adjacent to the secondlower region 212, the second upper region 232, and the first and thirdmiddle regions (221 and 223, respectively), and the fourth middle region224 is adjacent to the fourth lower region 214, the fourth upper region234, and the third and fifth middle regions (223 and 225, respectively).At least one of the regions is a hybrid region formed of a passive orelectro-optic material such that at least one of the followingconditions is satisfied:

1. in a cross-section taken at one point along the path of the opticalsignal, at least one of the second or fourth lower or upper regions orthe first, second, third, fourth, or fifth middle regions has a hybridportion, and in a cross-section taken at another point along the path ofthe optical signal, the same region has a non-hybrid portion;

in a cross-section taken at one point along the path of the opticalsignal for evanescently-coupled cores:

2. when the second or fourth lower region is the hybrid region, theother of the second or fourth lower region is formed of a claddingmaterial having a refractive index that differs from the refractiveindex of the hybrid region;

3. when the second or fourth upper region is the hybrid region, theother of the second or fourth upper region is formed of a claddingmaterial having a refractive index that differs from the refractiveindex of the hybrid region;

4. when the first, third, or fifth middle region is the hybrid region,at least one of the other of the first, third, or fifth middle region isformed of a cladding material having a refractive index that differsfrom the refractive index of the hybrid region; and

5. when the second or fourth middle region is the hybrid region, theother of the second or fourth middle region is formed of a core materialhaving a refractive index that differs from the refractive index of thehybrid region.

Further, the invention provides new methods of making these structures.The methods place a material of different optical properties (e.g. adifferent refractive index) either (1) within a core in the structure or(2) within the cladding of the structure and sufficiently close to acore to affect the electric field of an optical signal being carried bythe core. A rib-based method can be used to make a structure of thisinvention, wherein a rib of core material is formed as the structure ismade, and either a portion of the rib or a portion of the claddingabutting the rib is a hybrid portion. One rib-based method is based onforming a cavity in a layer of a first core material, filling the cavitywith a second core material, and removing a sufficient amount of thefirst core material to form a core having a length, a width, and aheight such that the core has a portion along its length wherein thesecond core material spans the width and height of the core, and thesecond core material is located between two portions of the first corematerial of the core. Another rib-based method is based on forming acore comprised of a core material on a layer of a first claddingmaterial and placing a second cladding material adjacent to at least oneside of the core such that the second cladding material abuts that sideof the core.

Another method for making a structure of this invention is atrench-based method, wherein a channel is formed and the channel isfilled with core material as the structure is made, and either a portionof the core or a portion of the cladding abutting the core is a hybridportion. One trench-based method is based on forming a channel in alayer of a cladding material, filling at least a portion of that channelwith a first core material, forming a void in the first core material,and filling the void with a second core material. Another trench-basedmethod is based on embedding a region of a first cladding material intoa layer of a second cladding material, and forming a core within thelayer of cladding such that both cladding materials abut the core on thesame side of the core.

A temporary filler may be used in the processes described above. Thetemporary filler is placed in at least a portion of the structure (thecore and/or the cladding) during manufacturing to allow portions of thestructure to be fabricated of a material that differs from itssurrounding material. The temporary filler is masked and partiallyetched, a first material is placed into the vacancies created byremoving some of the temporary filler, and the remainder of thetemporary filler is subsequently removed and replaced with a materialthat differs from the first material. This method can be used in thetrench-based manufacturing process, wherein cores are formed in trenchescut into a substrate, or a ribbased manufacturing process, wherein ribcores are formed by etching a substrate and subsequently filling-in theetched portion with a cladding material. These methods produce regionsof cores and/or cladding that have e.g. different refractive indicesfrom surrounding materials.

Among other factors, the invention is based on the technical findingthat a hybrid waveguide structure made by etching a substrate and usinga temporary filler to provide cores or cladding with differentrefractive indices provides: (1) isolation between cores that can bevaried; (2) a very small turning radius for cores; (3) very consistentperformance between one batch of waveguides and/or switches andsubsequent batches of waveguides and/or switches; (4)accurately-controlled dimensions and consistent performance because ofthe method of making the structure; (5) little overall loss of opticalsignal despite the use of materials in the structure that create highsignal losses; (6) smaller devices or devices that have more componentsfor a given size; and (7) unique device structures that act as filters,tapers, and switches that could not be made using a single material set.Further, the methods supplied by this invention align major structuralelements such as hybrid cores to very accurate dimensions because theseelements are established in a single photolithographic step. Also, themethods of this invention require few photolithography steps in which asubstrate must be removed and repositioned within a stepper multipletimes, so that cores and cladding can be made to precise dimensions.These technical findings and advantages and others are apparent from thediscussion herein.

DESCRIPTION OF THE FIGS.

The Figures illustrate certain preferred embodiments of the invention,and, consequently, the claims are to be given their broadestinterpretation that is consistent with the specification, the drawings,and the meaning of terms used herein to one of ordinary skill in theart.

FIG. 1 illustrates a known interferometric switch.

FIG. 2 illustrates a hybrid waveguide structure having three sections, alower section, a middle section, and an upper section, and wherein eachsection has a first, second, third, fourth, and fifth region.

FIG. 3 illustrates a waveguide having cladding buttons made by themethod of this invention.

FIG. 4 shows an interferometric demodulator having a core button and acladding button, respectively.

FIGS. 5A and 5B illustrate the structure of various electro-opticmaterials that can be used to make the structure of this invention.

FIGS. 6A-6J illustrate a trench-based manufacturing method formanufacturing an optical waveguide or switch that has a core button.

FIGS. 7A-7F illustrate a trench-based manufacturing method formanufacturing an optical waveguide or switch that has a cladding button.

FIGS. 8A-8F show a rib-based manufacturing method for manufacturing anoptical waveguide or switch that has a core button.

FIGS. 9A-9G illustrate a rib-based manufacturing method formanufacturing an optical waveguide witch that has a cladding button.

FIG. 10 shows an interferometric demodulator having both a core buttonand cladding buttons.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

The invention provides a hybrid waveguide structure and methods ofmaking a hybrid waveguide structure. A hybrid waveguide structurecomprises at least one core that carries an optical signal and claddinginto which the electric field of the optical signal being carried by thecore extends, wherein at least a portion of a core and/or a section ofits cladding has optical properties (e.g. a refractive index) thatdiffers from the optical properties of a neighboring core or portion ofthe same core or cladding area, respectively. Thus, in a hybridwaveguide structure, a core may have a section that has a refractiveindex that differs from the refractive index of the remainder of thecore or that differs from the refractive index of another core, and/orthe cladding near a core may have a section that has a refractive indexwhich differs from the remaining cladding around the core. Thedescription of some preferred embodiments of a hybrid waveguidestructure follows. Although these preferred embodiments describe coresthat are aligned within a single layer, this invention also encompassesstructures in which optical cores are provided in multiple layers.

1. Waveguides and Switches

As described previously, a hybrid waveguide structure can have a singlechannel core wherein a portion of the core or a portion of the claddingaround the core has a refractive index that differs from the refractiveindex of other portions of the core or the cladding, respectively. Or, ahybrid waveguide structure can have multiple channel cores wherein atleast a portion of one core or at least a section of the cladding has arefractive index that differs from the refractive index of another coreor another section of cladding, respectively. Examples of each of thesestructures follow.

(a) Hybrid Single-core Structure

In one preferred embodiment of the invention, the hybrid waveguidestructure has a “button” wherein a short section of the core or itssurrounding cladding has a refractive index that differs from therefractive index of a neighboring portion of the same core or claddingarea, respectively. A “button” is very useful in devices where thedevice designer wishes to modify characteristics of the optical signallocally to provide the device with unique properties.

One example of a hybrid waveguide structure having a “button” is shownin FIG. 3. A single channel core 310 interconnects switches or othersignal processing features that are fabricated on a substrate. The coremakes two 90° turns that the optical signal must follow.

Prior structures used the same cladding material to surround thestraight portion and the curved portion of the core. In these devices,each 90° turn required a turning radius of at least 10 mm where thecladding had a refractive index of 1.519 and the core had a refractiveindex of 1.520 in order not to lose optical power out of the core intothe cladding. Two 90° turns add 20 mm of length into the overall lengthof this prior structure.

The hybrid waveguide structure illustrated in FIG. 3 has cladding 320surrounding the curved portion of the core which has a much lowerrefractive index than the cladding 330 surrounding the straight portionsof the core. This “cladding button” in the core reduces the radius inthe core from 10 mm in the prior device to only 1 mm where the core hasa refractive index of 1.600, the curved section of cladding 320 has arefractive index of 1.500, and the remainder of the cladding has arefractive index of 1.590. The hybrid waveguide structure illustrated inFIG. 3 is thus 18 mm shorter than the prior structure and hasessentially equivalent performance to the prior structure. This shorterlength is a distinct advantage regardless of whether a waveguidestructure or switch of this invention is used in a hybrid componentdevice, wherein a waveguide or switch is connected to other discretecomponents, or in an integrated device wherein many components areplaced on one substrate.

(b) Hybrid Multi-core Structure

The hybrid multi-core structure has at least two cores and surroundingcladding. A hybrid multi-core structure can have a “button,” or a hybridmulti-core structure can have a core that has a different refractiveindex from another core or a region of cladding which is adjacent to acore and which has a different refractive index from another region ofcladding adjacent to the core.

A “button” can be used in an interferometric device such as a hybridwave multiplexer or filter. FIG. 4 shows an interferometric multiplexer400 wherein one of the cores 410 has a “core button” 420 in which asection of the core has a refractive index that differs from adjoiningportions of the same core. FIG. 4 also shows a “cladding button” 430 inwhich a section of the cladding has a refractive index that differs fromadjoining portions of the cladding. The use of a “button” delays theoptical signal in that core relative to the optical signal in the secondcore, which results in a suitably modified optical signal emerging fromthe multiplexer after the signals from the two cores are coupledtogether and outputted from output sections of the cores. In thisparticular device, the difference between the refractive indices of thecore and cladding buttons is at least approximately equal to thedifference between the refractive indices of the core and cladding thatneighbor the core and cladding buttons, respectively.

(c) Further Discussion of Hybrid Waveguide Structure

In certain embodiments, a hybrid waveguide structure of this inventionhas a core or cores that are sandwiched between optionalelectric-field-generating electrodes. The hybrid waveguide structure canbe viewed as having three sections, as illustrated in FIG. 2: a middlesection 220 containing at least one core 222 (or containing at least twocores 222 and 224) in core regions and cladding 221 and 223 (and 225when the structure has at least two cores) in cladding regions adjacentto the cores; a lower section 210 that typically contains cladding inregions that affect the optical signal in the cores; and an uppersection 230 that also typically contains cladding in regions that affectthe optical signal in the cores (usually a position immediately adjacentto the cores). At least one of the materials used in the core orcladding regions has optical properties (e.g. a refractive index) thatdiffer from the optical properties of another material used in the coreor cladding regions, respectively.

Thus, for example, one portion of a core in a structure having only onecore may be formed from a passive material having a refractive index of1.520, and another portion of that core may be formed from a passive oractive material that has a refractive index of 1.510 in e.g. thepresence of an electric field. Likewise, for example a cladding regionin the upper section, e.g. 232, that affects the optical signal in thecore can be formed from a first electro-optic material that experiencesa change in refractive index of e.g. 0.010, and another region in thelower section that affects the optical signal in the core (e.g. 212) canbe formed from a passive material or a second electro-optic materialthat experiences a change in refractive index of e.g. 0.005 when anelectric field is applied to the structure.

Other examples include the following structures having two cores. In afirst example, region 222 can be made of a passive core material havinga refractive index of 1.520, and region 224 can be made of a passive orelectro-optic core material having a refractive index of 1.510 in e.g.the absence of an electric field. Likewise, in a second example, regions222 and 224 can be made of a passive core material having a refractiveindex of 1.520, and at least one of regions 212, 214, 221, 223, 225,232, and 234 is a passive or electro-optic cladding material that has arefractive index that differs (in either the presence or the absence ofan electric field) from one of the cladding regions in the structure. Ina third example, sections 210 and 230 are made of a passive claddingmaterial having a refractive index of 1.560, regions 222 and 224 aremade of a passive core material having a refractive index of 1.60, andregions 221, 223, and 225 are made of a passive cladding material havinga refractive index of 1.590. In a fourth example, a device has regionsas in the third example above, but region 223 is an electro-opticcladding material that has a refractive index equal to that of regions221 and 225 in the absence of an electric field.

The optical signal introduced into one end of a core has an electricfield portion of the optical signal that extends into the surroundingcladding and into a coupled core, if present. In a hybrid waveguidestructure, the optical signal encounters a region in the core and/or inthe cladding wherein the refractive index of that region changes. Thechange in refractive index affects the electric field of the opticalsignal and thus changes the optical signal itself. The length, width,height, and refractive index of the hybrid portion and the length,width, height, and refractive index of the remaining core and claddingare selected to provide the desired modifications (such as phase shiftor distribution of power of the optical signal in evanescently-coupledwaveguides) to the optical signal. If the core that is initiallycarrying the optical signal is evanescently coupled to other cores, alloptical signals in the cores are simultaneously changed by the change inrefractive index, and the power exiting each core can be distributed asdesired by selecting the length of the cores and regions, their widthand height, the width and height of cladding regions, and the refractiveindex of each region. If an electro-optic material is used in the hybridregion, a change in electric field can be used to distribute a desiredamount of the optical signal from the input core to any or each of theoutput cores or to induce a phase shift in an optical signal travelingthrough a single core.

The preferred refractive index of the hybrid portion depends upon thefunction of the hybrid portion in the particular optical device to befabricated. Cladding buttons 320 in the waveguide of FIG. 3 preferablyhave a refractive index which differs substantially from the refractiveindex of its surrounding cladding (at least 0.01 units difference to asmuch as 0.05-0.1 units or more) in order to assure the neededdirectional change in the optical signal without introducing undesiredmodes of substantial strength into the optical signal. Passive core andcladding buttons (420 and 430, respectively) of the interferometricdemodulator of FIG. 4 preferably each have a refractive index whichdiffers substantially from the refractive index of the surrounding coreand cladding, respectively (at least 0.01 units difference to as much as0.05-0.1 units or more), while preferably the difference between therefractive index of the core and cladding buttons is equal to thedifference between the refractive index of the surrounding core andsurrounding cladding to prevent introducing additional modes ofsubstantial strength into the optical signal. For coupled waveguidessuch as those illustrated in FIG. 2, the refractive index of the hybridportion is approximately equal to its neighboring materials (in manyinstances, no more than about ±0.001 units different from itscorresponding non-hybrid material). The change in refractive index thatan electro-optic material experiences is selected depending on thedesired change in optical signal and the dimensions of the opticaldevice in which the electro-optic material is incorporated, and atypical change in refractive index for coupled waveguides is 0.010units. Using a core or cladding material in the hybrid portion, whichmaterial has properties that are similar to its surrounding materials,can provide the ability to change the electric field of the opticalsignal a controlled amount and thus can affect the properties of thesignal without substantial loss of signal energy or addition of modes orharmonics to the optical signal.

The materials from which the core, cladding, and hybrid portions of thehybrid waveguide structure are formed may be passive materials that donot change refractive index appreciably in the presence of an appliedelectric field; or, a hybrid portion, a core, or cladding may be e.g. anelectro-optic material individually or in any combination. For example,in an “active” or “electro-optic core button,” a cladding made of apassive material contains a hybrid core with a short section ofelectro-optic material which adjoins the passive material forming theremainder of the core. Also by way of example, in an “active claddingbutton,” a core made of a passive material is embedded in a claddingmade mostly of passive material but which contains a short claddingsection of electro-optic material that is adjacent to the core. Anelectric field is applied to these electro-optic “buttons” to change therefractive index of the electro-optic material incorporated in the“buttons.” Planar, strip, or circular electrodes, for example, can bepositioned above the “button,” or an electrode can be positioned abovethe “button” and one can be positioned below it. It is not necessary togenerate the electric field to which the electro-optic material isexposed with electrodes. Any electric field-generating equipment can beused that generates an electric field sufficiently strong to change therefractive index in an electro-optic material present in the structure.For example, wires carrying a large current can be positioned aboveand/or below the electro-optic material. Likewise, a corona field or anelectrostatic discharge from e.g. charged particles can be used togenerate the electric field. Other materials that change refractiveindex in response to a signal may be used in place of or in addition toan electro-optic material. Such materials include thermooptic,elastooptic, magnetooptic, and acoustooptic materials.

There are many examples of optical materials from which a hybridwaveguide structure can be fabricated. A difference in refractive indexcan be achieved by using different materials in the cores and/or thecladding or by applying an electric field to an electro-optic polymer.Electro-optic polymer materials are preferred electro-optic materials.Chromophores such as DR-1, DCM, RT2108, RT 4210, or SY215 may be graftedonto passive materials such as Amoco Chemical Corporation's Ultradel4212 or Hitachi Chemical Corporation's PIQ L100, OPI 1305, or OPI 2005to form an electro-optic material (see FIGS. 5A and 5B for thestructures of these materials, where “A” on the polymer structure may beany of the substituents shown in “a,” “b,” or “c”). Other electro-opticpolymers include Enichem's polymers disclosed in U.S. Pat. Nos.5,395,556 and 5,514,799, each of which is incorporated by referenceherein. A hybrid digital electro-optic switch made with an electro-opticpolymer can be manufactured easily and at low cost. Electro-opticmaterials can also be large bandgap crystals (such as LiNbO₃ or KNbO₃)or semiconductors (such as GaAs, InGaAs and other Group III-V compounds)that have been doped with a metal such as titanium to form cores andcladding regions. A hybrid digital electro-optic switch can also befabricated into a multiple-quantum-well device by e.g. chemical vapordeposition to become a very low switching voltage device. Passivematerials have little or no electro-optic effect, and typical examplesof passive materials include Amoco's Ultradel 4212 and Hitachi's PIQL100, OPI 1305, and OPI 2005. Cladding materials can be electro-optic orpassive materials such as polyimide, polyacrylate (such aspolymethylmethacrylate), benzyl-cyclobutene, or polyquinoline. Thematerials used to produce cores and/or cladding can be selected from awide range of materials, including organic materials, inorganicmaterials and hybrid organic/inorganic materials, such as sol-gelglasses in a polymeric matrix. The electro-optic material in a core orcladding preferably has a refractive index equal to the refractive indexof its neighboring core or cladding, respectively, either in thepresence or absence of an applied electric field.

Core and cladding materials are preferably polymeric materials. Thesematerials are easily handled in the method of this invention describedbelow. Also, the refractive index of a batch of these materials can bedetermined before fabricating a structure, and the dimensions of eachcore and cladding can be determined and adjusted to provide consistentperformance of a structure despite variations in material properties.

Electro-optic and passive “buttons” can be located at points of closeapproach or contact and/or between two or more adjacent optical cores toprovide variable or fixed coupling between these cores, respectively.Control signal paths are routed to make electrical contact withelectrodes above and below electro-optic buttons to enable control overthe optical states of these buttons. An “off state” of an electro-opticcore button can be selected such that the refractive index of theelectro-optic material is essentially equal to that of the passivematerial of the optical core within which it is located so that theoptical signal is outputted from the same core into which it isinputted. In an “on-state” of an electro-optic button, the refractiveindex of the electro-optic material of the core button is reduced sothat at least a portion of the optical signal is outputted from theother core.

Hybrid waveguide structures can be designed using Maxwell's equations,Marcatili's method, or the effective index method, for example, asdescribed in H. Nishihara et al., OPTICAL INTEGRATED CIRCUITS, pp. 29-32and 46-61 (1985) (McGraw-Hill). For a hybrid waveguide structurecontaining two or more evanescently-coupled cores, usually the couplinglength of the cores is selected during design, and the other designparameters such as material refractive index and width, height, andseparation of cores are chosen to provide the desired switchingcharacteristics for the particular application in which the hybridwaveguide structure is to be used. The hybrid section of a hybridwaveguide structure containing one core is usually designed to inducethe desired phase-shift in the optical signal or to provide the desiredvalue for the maximum angle of reflection of the optical signal atbends. The maximum thickness of the hybrid waveguide structure isusually established by the voltage that is available to produce theelectric fields that act on the electro-optic material in the core.Where the hybrid waveguide structure has hybrid cladding, the hybridsection is sufficiently large and sufficiently close to the core tocause a desired amount of change in the electric field of the opticalsignal traveling through the core.

One advantage of many of the hybrid waveguide structures of thisinvention is that the structure can carry a single-mode optical signalwithout adding optical modes. Thus, a single-mode optical signal is alsooutputted from the structure.

The U.S. patent application, “Hybrid Digital Electro-optic Switch,”inventors John T. Kenney and Richard D. Sherman, was filed on even dateherewith and describes other and additional aspects of this invention.The disclosure of Mr. Kenney's and Mr. Sherman's patent application isincorporated by reference herein in its entirety for all that theapplication teaches.

Hybrid waveguide structures can be incorporated into equipment used forsuch purposes as:

(I) signal equalization in regenerative amplifiers fortelecommunications;

(II) logic elements in an all optical or hybridized optical logiccircuit;

(III) wavelength conversion elements in wavelength division multiplexingand demultiplexing switching systems for telecommunications;

(IV) external modulation of optical signals for digital signaltransmission; and

(V) an n-by-n crossbar switch used in telecommunications.

2. Methods of Making the Hybrid Waveguide Structure

The invention provides methods of making a hybrid waveguide structure.The invention provides a “trench-based manufacturing process,” in whichrelatively shallow trenches are cut into a material and filled witheither a core or a cladding material. The invention also provides a“rib-based manufacturing process,” in which cores are formed in ribs bycutting into a multi-layer material (at least one layer or portion ofwhich is usually core material) and filling the deep troughs withcladding material. Many of these methods utilize a temporary filler thatallows two optical materials to be placed in the trench or trough invery specific and well-controlled locations. One of the advantages ofmethods described below is that the cores within a layer are“self-aligned.” The trenches or ribs in which the cores are formed arepatterned in one photolithography step. Thus, even though portions ofcores may be made of different materials, the trenches or ribs align toone another without the need to etch additional trenches and attempt toalign the new trenches with previously-etched trenches.

Many electro-optic materials absorb substantial energy from the opticalsignal and can only be used in existing core structures in very limitedcircumstances. The process of this invention allows these “lossy”materials to be used in cladding buttons or in core buttons in thespecific coupling, switching, or modulating region with little loss ofthe optical signal.

(a) Trench-based Manufacturing Process

In the trench-based manufacturing process, an optional electrode isformed on the surface of a substrate that is subsequently coated withe.g. a layer of a high-clarity, passive material that will function asthe cladding for optical cores that are to be formed. Aphotolithographic process and associated etch (wet or dry) produces anopen trench or a plurality of open trenches (e.g. two or more) in thispassive material. At least one of these trenches is filled with atemporary, easily-etched filler material. This temporary filler issubsequently masked and etched to remove selected portions of the fillermaterial. Portions within a trench may be removed to leave one or moreshort sections (referred to herein as “space-filler buttons”) oftemporary filler in one or more of the trenches, or, all of thetemporary material in selected trenches may be removed so that someempty trenches and some trenches partly or wholly filled with temporaryfiller are provided.

The empty sections of each trench are filled with a second high-claritymaterial having a different property from the first material, and thestructure is subsequently planarized by etching the structure or byusing e.g. chemical-mechanical polishing (CMP). A secondphotolithography step may be performed so that a portion of theremaining temporary material can be etched and the resulting spacefilled with a third high-clarity material and so forth until alltemporary material has been removed and filled with high-claritymaterial that has been planarized. Usually a layer of passive materialis spun onto the structure, and subsequently an electrode or electrodesare formed above and near any electro-optic material incorporated intothe structure.

Some specific examples of this process illustrate some of the benefitsthat are derived from using the trench-based manufacturing process tomake hybrid waveguide structures.

(i) Core Button Made by Trench-based Manufacturing

FIG. 6A illustrates a top portion of a wafer 10 on which a firstcladding layer 11, such as polyimide, has been spun coated and anelectrode, 9, has been formed. Trenches 12 (illustrated in FIG. 6B) areformed in cladding layer 11 by applying a masking layer 13 (photoresistor metal) to a top surface 14 of the first cladding layer and thenpatterning this masking layer, developing the exposed layer to produce acontact mask having an elongated rectangular opening 15 in the maskinglayer, and then etching the exposed portion of layer 11 in a wet or adry etch to form trenches 12.

As illustrated in FIG. 6C, a layer of temporary filler 16 is e.g.sputtered or deposited via CVD onto cladding layer 11 to fill trenches12. Next, as illustrated in FIG. 6D, a photolithographic mask 18,consisting of a conventional photolithographic material, is formed ontop of surface 16 by conventional techniques. The top surface of thisstructure can be planarized at this point, if desired. Temporary filler16 is patterned via photolithography, and the exposed portions 19 oftemporary filler 16 is subsequently etched to form a temporary button110 of FIG. 6E. A metal such as aluminum is a particularly good choicefor the temporary filler, because the metal can be easily etched by awet etch process that uses an acid bath such as a phosphoric/nitric acidbath without harming the polymer and substrate.

As illustrated in FIG. 6F, a layer of core material 111 is deposited toa thickness sufficient to fill in a set of trench openings 112(illustrated in FIG. 6E) with core material to form core segments 113illustrated in FIG. 6G. The top surfaces of the core material isplanarized to produce top surfaces (illustrated in FIG. 6G) that are, inthis case, coplanar with a top surface 14 of the first cladding layer.This planarization also exposes the temporary filler buttons 110. Thisfigure illustrates core segments 113 and one of the temporary fillerbuttons 110.

The temporary filler buttons 110 are removed (e.g., by etching with asuitable etchant) to produce button openings 114 shown in FIG. 6H. Asillustrated in that figure, a layer of optical material 115 is appliedto fill in the button openings 114, thereby producing the buttons 116,illustrated in FIG. 61. Thus buttons 116 can be formed of passivematerial having a refractive index that essentially does not change inresponse to an applied electric field, or buttons 1 16 can be anelectro-optic material that changes refractive index in the presence ofan applied electric field. For example, it may be advantageous to use apassive button to produce a fixed amount of coupling between a pair ofclosely-spaced optical cores. Alternatively, a passive button can beused merely to introduce a fixed delay in an optical signal path.

A second cladding layer 118 (illustrated in FIG. 6J) of the samecladding material used to form first cladding layer 11 is applied, andelectrode 119 is formed above at least core button 116. A backplaneelectrode 9 is included so that an electric field can be generated tochange the refractive index of the electro-optic material.

(ii) Cladding Button Made by Trench-based Manufacturing

In this trench-based manufacturing method, a substrate 701 shown in sideview in FIG. 7A is coated with a first layer of a cladding material 702.A second layer of a second cladding material 703, having a refractiveindex greater than the refractive index of the first cladding material,is deposited on the first cladding layer in this example, patterned viaphotolithography, and etched to produce cavities 704 illustrated in thetop view of FIG. 7B (this second layer is optional and may beeliminated). These cavities are located in areas through which a core orcores of the structure will run after processing is completed. Thecavities are etched through the second cladding material of the secondlayer and to the surface of the first layer as illustrated in the sideview of FIG. 7C. Etch depth is controlled by timing the etch or by usinga laser interferometer.

The cavities are filled with a third cladding material 705 andplanarized via, e.g., dry etching. The structure is again patterned viaphotolithography and etched to the first cladding layer to definechannel 706 of FIG. 7E. The channels so formed are filled with a corematerial and planarized to form core 707 and the structure shown in FIG.7F. Subsequently, the structure is coated with a fourth claddingmaterial which e.g. is the same cladding material used to form the firstlayer. Electrodes may be added to the structure where the material usedto form the cladding buttons is an electro-optic material. Preferably,the third cladding material that is used to fill the core wells iselectro-optic material. A temporary filler is not needed in this method.

(b) Rib-based Manufacturing Process

A “rib-based manufacturing process” can also be used to manufacturehybrid waveguide structures having e.g. core or cladding buttons.Generally, in a rib-based manufacturing process, cores are containedwithin ribs that are fabricated of optically-transmissive materials, andcladding material is placed between the ribs. A temporary filler is usedin methods of this invention so that materials having differentrefractive indices (or having differences in other useful properties)can be placed in portions of the structure being fabricated.

(i) Core Button Made by Rib-based Manufacturing

In one rib-based manufacturing process, a substrate 801 shown in sideview in FIG. 8A is coated with a first layer of a cladding material 802.A second layer of a first core material 803 is deposited on thiscladding layer, patterned via photolithography, and etched to producecavities 804 illustrated in the top view of FIG. 8B. These cavities arelocated in areas that will eventually become the cores of the structureafter processing is completed. The cavities are etched through the firstcore material of the second layer and to the surface of the substrate orto the surface of the cladding material of the first layer asillustrated in the side view of FIG. 8C. Etch depth is controlled bytiming the etch or by using a laser interferometer.

The cavities are filled with a second core material 805 and planarizedvia, e.g., dry etching. The structure is again patterned viaphotolithography and etched to the substrate or to the first claddinglayer to define the ribs 806 and 807 of FIG. 8E that contain the cores.The cavities 804 so formed are usually sufficiently wide that the secondcore material 805 occupies the full width of the rib 806 in which thesecond core material is incorporated. Subsequently, the etched structureis coated with a second cladding material 808 that also fills thetroughs or open spaces between the ribs as shown in FIG. 8F. Therefractive index of the second cladding material 808 can be the same asor can differ from the refractive index of the first cladding material802. Electrodes may be added to the structure where one of the materialsused in forming the core buttons is an electro-optic material.Preferably, the second core material that is used to fill the core wellsis electro-optic material. A temporary filler is not needed in thismethod.

Ribs or portions of ribs containing the second core material may bespaced sufficiently far from one another that they do not evanescentlycouple. In this case, the second core material induces a phase shift inthe optical signal being carried in its core. Ribs or portions of ribsmay be spaced sufficiently closely that the cores evanescently couple inuse. The core button that is formed in one of the evanescently-coupledcores alters the optical signal in all evanescently-coupled cores afixed amount if the second core material is a passive material, or thecore button can alter the optical signal a predictable amount if thesecond core material is an electro-optic material.

(ii) Cladding Button Made by Rib-based Manufacturing

FIGS. 9A-F illustrate a rib-based manufacturing process formanufacturing a hybrid waveguide structure that has a cladding button.These figures also illustrate a particular embodiment in which threecoplanar optical cores are formed to approach sufficiently closely thatthe cores evanescently couple.

FIG. 9A illustrates a top portion of a wafer 20 on which a layer of afirst cladding material 21 has been deposited. A layer of a corematerial 22 is deposited on cladding layer 21. A subsequently-depositedlayer of photolithographic material 23 is exposed through a mask and isdeveloped to produce a plurality of mask regions 24-26 shown in FIG. 9B.The layer of core material 22 is etched in those regions that are notprotected by mask regions 2426, thereby producing a set of cores or ribs27-29 shown in FIG. 9C.

As illustrated in FIG. 9D, a layer of temporary filler (e.g., a metalthat can be etched by acids that will not attack the other components ofthis device) is applied to fill the troughs, patterned viaphotolithography, and etched to leave a section of temporary filler 30where the button is to be located in the completed hybrid waveguidestructure. At this point, the structure may be completed two differentways in these preferred embodiments of the invention.

A second cladding material 31 (which preferably has the same refractiveindex as the first cladding material) is applied to the structure, andthe second cladding material is planarized using e.g. dry etching orreactive-ion etching. The embedded sections of temporary filler areexposed by patterning and etching the structure to remove the secondcladding material above the temporary filler. The temporary filler isetched to form voids 32 as shown in FIG. 9F, and a third claddingmaterial 33 is coated onto the structure to fill the voids as shown inFIG. 9G. If the third cladding material is a passive material, usuallyenough of the third cladding material is placed on the structure thatthe third cladding material both fills the voids and forms a claddinglayer over the cores. If the third cladding material is an electro-opticmaterial, usually the layer of third cladding material is planarizedusing e.g. dry etching to remove the electro-optic material from allareas except the areas where the temporary filler resided. Suchplanarization can be accomplished by first coating the layer to beplanarized with a sacrificial layer having a similar etch rate to theunderlying material (such as photoresist or benzyl-cyclobutene(“benz-cyclobutene” or “cyclotene”) of at least sixty percent solids),curing the layer, and etching the sacrificial layer and the underlyinglayer until the surface of the remaining underlying layer issubstantially planar with the surface of the structure that existedprior to placing the underlying layer on it.

If the third cladding material is an electro-optic material, a fourthcladding material is spun onto the structure to form a cladding layerabove the cores, and electrodes are optionally formed over theelectro-optic material. A backside electrode is also optionally formedunder electro-optic buttons at the beginning of the process so that,when an electrical voltage is applied to a top electrode located over anelectro-optic cladding button, an electric field is produced through theelectro-optic cladding button to vary the refractive index of thatbutton.

Alternatively, instead of completing the structure as described in theprevious two paragraphs, the following method may be used to completethe structure. A second cladding layer is spun onto the structure asdescribed in the third paragraph preceding this paragraph and planarizedto the tops of cores 27, 28, and 29, the temporary filler is removed,and the cavity is filled with e.g. the third cladding material describedabove. The structure is again planarized, and a fourth cladding layer isthen spun on to complete the structure.

Electro-optic cladding buttons can be taller or shorter than or the sameheight as cores 27-29. The electro-optic cladding buttons may be betweenor may completely surround waveguides 27-29. At their point of closestapproach, cores 27-29 are separated by a spacing of approximately 2-3wavelengths or less, so that light is efficiently coupled between thesecores. The electro-optic material may extend only part way betweenadjacent ribs, but preferably extends across the entire gap betweenadjacent ribs.

In this particular embodiment, the sidewalls of this button curve in amanner similar to the curved sidewalls of ribs 27 and 29. Preferably,this cladding button is wide enough that it contacts all three of theseribs 27-29, thereby providing cladding material that extends completelyacross the gap between each pair of adjacent ribs in the region wherethese ribs are most closely spaced. Instead of or additionally toplacing cladding material in the curving portion of the cores,electro-optic material may be placed between the evanescently-coupledcores to effect a change in the optical signal being carried by thecores in response to an applied electric field.

(iii) Combinations of the Above Methods

Although much of the discussion above has been in terms of electro-opticbuttons, it is generally advantageous to utilize both electro-active andpassive buttons in a device incorporating hybrid waveguide structures toprovide a wider range of functions on a device. For example, a passivecore button can be used to provide cores with short-radius bends thatact as conduits between different switches that are incorporated into adevice. Interferometric switches, Δβ directional couplers, branchingwaveguide switches, total internal reflection switches, and/or multimodestar or multimode interference couplers that have electro-optic coreand/or cladding buttons, for instance, can also be incorporated into thesame device to process the optical signal. The methods of making hybridwaveguide structures discussed above allow easy incorporation of any orall of these switches and other structures into one device because themethods permit patterning, etching, and forming the devicessimultaneously.

One example illustrates how the above methods can be combined to formdifferent hybrid waveguide structures. An interferometric filter used todemultiplex optical signals is illustrated in FIG. 10. Thisinterferometric filter is fabricated by forming both cladding buttonsand a core button using passive materials.

A first passive cladding material having a refractive index of 1.5100 isspun onto a silicon substrate or a silicon substrate having an oxidelayer, and a rectangular section of the cladding through which a corewill eventually run is patterned via photolithography and etched to forma rectangular trench in the substrate. A second passive claddingmaterial having a refractive index of 1.6100 is spun onto the layer ofthe first passive cladding material, filling the void and forming alayer on the first passive cladding material.

The second passive cladding material is planarized using e.g.photoresist and a dry etch, leaving only a rectangular section of thesecond passive cladding material embedded within the first passivecladding material. The structure is patterned via photolithography, andtwo trenches are cut into the passive cladding materials. One trenchpasses through the middle of the rectangular section of the secondcladding material, and the other trench passes through the firstcladding material. This etch has established critical features of theinterferometric switch, the width, height, and spacing of the cores to atolerance of about 0.1 micron.

Next, a temporary filler is deposited on the structure, patterned viaphotolithography, and etched so that temporary filler remains onlywithin the portion of the trench passing through the rectangular sectionof the second cladding material. A first core material having arefractive index of 1.520 is spun onto the structure, and the layer isplanarized so that the first core material remains only within thetrenches. The temporary filler is etched, and the structure is coatedwith a second core material having a refractive index of 1.620, which isplanarized so that the second core material remains only within the voidin the trench left when the temporary filler was removed. A thirdpassive cladding material that is identical to the first passivecladding material is spun onto the structure, and a rectangular sectionis patterned over the previously-formed rectangular section. Therectangular section of the third passive cladding material is etched tothe second core material to form a rectangular trench, and subsequentlya fourth passive cladding material that is identical to the secondpassive cladding material is spun onto the structure to complete it. Theresulting hybrid waveguide structure has two cores 1001 and 1002embedded in cladding material, and the structure has a core button 1003and cladding button 1004.

An optical signal consisting of two different wavelengths of lightenters the filter through an input core, splits into twin signals at ajunction, and each signal passes through a core. One of the cores 1001has hybrid core and cladding buttons, wherein the phase of the signal inthat core is shifted when its phase is compared to the phase of itsformer twin signal passing through the other core. The coressubsequently approach each other and are sufficiently close togetherthat evanescent coupling occurs between the cores. As the cores divergeagain, one core carries light of wavelength λ₁, and the other corecarries light of wavelength λ₂. These signals can be used in otherswitches located down-stream of the interferometric filter justdescribed.

This example illustrates various advantages of this invention. Criticaldimensions of cores can be established in one photolithography step,which establishes those dimensions to an accuracy of about 0.1 micronusing current processing equipment. Less critical dimensions areestablished in steps that have less accuracy. For example, a maskaligner can reposition a substrate to an accuracy of only about ±1.0micron. Formation of cladding areas (which can be sized to be slightlyover-size or under-size without affecting the performance of the switch)is established in separate photolithography steps. Thus, using certainmethods of this invention establishes critical dimensions of features tohigh accuracy. Many combinations of materials may also be incorporatedinto the cores, the cladding, or both.

Descriptions of specific designs and dimensions are provided only asexamples. It is to be understood that various modifications to thepreferred embodiments will be readily apparent to those skilled in theart. Thus, while preferred embodiments of the invention have beendisclosed, it will be readily apparent to those skilled in the art thatthe invention is not limited to the disclosed embodiments but, on thecontrary, is intended to cover numerous other modifications and broadequivalent arrangements that are included within the spirit and scope ofthe following claims.

What is claimed is:
 1. An optical device comprising: (a) a first core;and (b) a second core; (c) wherein said first core and said second coreare positioned to receive identical input signals to each core; (d)wherein said identical input signals travel an optical path through eachcore; (e) wherein said first core is spaced sufficiently from saidsecond core that the optical signal in said first core is isolated fromsaid second core; (f) and wherein said first core forms part of a firstwaveguide that has at least one button selected from the groupconsisting of a core button and a cladding button, wherein the button ismade of a material that changes refractive index in response to astimulus.
 2. The optical device of claim 1 wherein, at a position thatis located after the button along said optical path, said first core andsaid second core converge to form one core.
 3. The optical device ofclaim 1 wherein, at a position that is located after the button alongsaid optical path, said first core and said second core are located onthe optical device so that the first core and the second core areparallel to one another and have a distance from one another such thatthe first core and the second core evanescently couple.
 4. The opticaldevice of claim 1 wherein said button is a cladding button.
 5. Theoptical device of claim 1 wherein said button is an electro-opticbutton.
 6. The optical device of claim 5 wherein said button is acladding button.
 7. The optical device of claim 5 further comprising anelectric field generator that generates an electric field of sufficientstrength to change the refractive index of the electro-optic button. 8.An optical device comprising, in cross-section, three sections, a lowersection, a middle section, and an upper section, wherein each sectioncomprises five regions, a first region, a second region, a third region,a fourth region, and a fifth region, (a) wherein the second middleregion and the fourth middle region are each formed of a core material;(b) wherein the other of the regions of each section are each formed ofa cladding material; (c) wherein a hybrid portion is a portion of aregion wherein, in the cross-section taken at one point along thedirection of the path of an optical signal traveling through a core, theportion comprises a first material having a first refractive index, andin a cross-section taken at another point along the path of the opticalsignal, the portion of the same region is a second material having asecond refractive index, wherein the first refractive index and thesecond refractive index are not equal, wherein a region containing thehybrid portion is a hybrid region and wherein the first material changesrefractive index in response to a stimulus; and (d) wherein at least oneof the following conditions is satisfied: (i) at least one of the secondor fourth lower or upper regions or the first, second, third, fourth, orfifth middle regions has a hybrid portion; (ii) in a cross-section takenat one point along the path of the optical signal where the secondmiddle region and the fourth middle region evanescently couple when anoptical signal is transmitted through one of these regions, when thesecond or fourth lower region is the hybrid region, the other of thesecond or fourth lower region is formed of a cladding material having arefractive index that differs from the refractive index of the hybridregion; (iii) in a cross-section taken at one point along the path ofthe optical signal where the second middle region and the fourth middleregion evanescently couple when an optical signal is transmitted throughone of these regions, when the second or fourth upper region is thehybrid region, the other of the second or fourth upper region is formedof a cladding material having a refractive index that differs from therefractive index of the hybrid region; (iv) in a cross-section taken atone point along the path of the optical where the second middle regionand the fourth middle region evanescently couple when an optical signalis transmitted through one of these regions, when the first, third, orfifth middle region is the hybrid region, at least one of the other ofthe first, third, or fifth middle region is formed of a claddingmaterial having a refractive index that differs from the refractiveindex of the hybrid region; (e) wherein the first refractive index andthe second refractive index are considered not equal when the firstrefractive index is not equal to the second refractive index in thepresence of the stimulus, in the absence of the stimulus, or both, and(f) wherein said core material comprises a noncrystalline material. 9.An optical device comprising: (a) a first core; and (b) a second core;(c) wherein said first core and said second core are positioned toreceive identical input signals to each core; (d) wherein said identicalinput signals travel an optical path through each core; (e) wherein saidfirst core is spaced sufficiently from said second core that the opticalsignal in said first core is isolated from said second core; (f) andwherein said first core forms part of a first waveguide that has atleast one button selected from the group consisting of a core button anda cladding button, wherein the button is made of a material that altersthe optical signal when the optical signal passes through said firstcore, and wherein the first core is formed of a noncrystalline material.10. The optical device of claim 9 wherein, at a position that is locatedafter the button along said optical path, said first core and saidsecond core converge to form one core.
 11. The optical device of claim 9wherein, at a position that is located after the button along saidoptical path, said first core and said second core are located on theoptical device so that the first core and the second core are parallelto one another and have a 1 distance from one another such that thefirst core and the second core evanescently couple.
 12. The opticaldevice of claim 9 wherein said button is a cladding button.
 13. Theoptical device of claim 9 wherein said button is an electro-opticbutton.
 14. The optical device of claim 13 wherein said button is acladding button.
 15. The optical device of claim 13 further comprisingan electric field generator that generates an electric field ofsufficient strength to change the refractive index of the electro-opticbutton.